Time density approach to managing en-route airspace

With the rapid growth in air travel and advancement in Air Traffic Management (ATM) technologies, the airspace is increasingly more complex and dynamic. These have adverse impact on Air Traffic Controllers’ (ATCO) monitoring performances and intensifying their workload. To cope with the challenging...

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Main Author: Tan, Brenda Teresa Li Min
Other Authors: Lye Sun Woh
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2020
Subjects:
Online Access:https://hdl.handle.net/10356/141169
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1411692023-03-04T19:41:15Z Time density approach to managing en-route airspace Tan, Brenda Teresa Li Min Lye Sun Woh School of Mechanical and Aerospace Engineering MSWLYE@ntu.edu.sg Engineering::Aeronautical engineering With the rapid growth in air travel and advancement in Air Traffic Management (ATM) technologies, the airspace is increasingly more complex and dynamic. These have adverse impact on Air Traffic Controllers’ (ATCO) monitoring performances and intensifying their workload. To cope with the challenging environment, the usage of models has been developed to aid in the identification of sectors with high workload. Presently, ATM systems using capacity modelling, such as the Monitor Alert Parameter, have limitations and are oversimplified in their approach. Moreover, not many studies have been done on improving the current system. Thus, the models are unable to fully capture the complexity at individual crossing points and the entire workload of the ATCOs. This study aims to investigate the relation of overall flight time within the sector and the number of aircraft around the crossing point to create a model to identify the risk of collision around the crossing point. ATCOs’ response time was used as the performance indicator in the study. It was found that the increase in flight time and the number of aircraft around the crossing point lead to an increased risk of collision. Factors like the number of aircraft in the entire sector and the headings of the aircraft around the crossing point were factors affecting the overall flight time and the number of aircraft around crossing point respectively. Using thresholds on the flight time and the number of aircraft, the model created was able to characterise the crossing points into 3 levels of risk. This helps to distinguish crossing points with higher chances of conflicts being missed out. Bachelor of Engineering (Aerospace Engineering) 2020-06-04T09:00:11Z 2020-06-04T09:00:11Z 2020 Final Year Project (FYP) https://hdl.handle.net/10356/141169 en B077 application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Aeronautical engineering
spellingShingle Engineering::Aeronautical engineering
Tan, Brenda Teresa Li Min
Time density approach to managing en-route airspace
description With the rapid growth in air travel and advancement in Air Traffic Management (ATM) technologies, the airspace is increasingly more complex and dynamic. These have adverse impact on Air Traffic Controllers’ (ATCO) monitoring performances and intensifying their workload. To cope with the challenging environment, the usage of models has been developed to aid in the identification of sectors with high workload. Presently, ATM systems using capacity modelling, such as the Monitor Alert Parameter, have limitations and are oversimplified in their approach. Moreover, not many studies have been done on improving the current system. Thus, the models are unable to fully capture the complexity at individual crossing points and the entire workload of the ATCOs. This study aims to investigate the relation of overall flight time within the sector and the number of aircraft around the crossing point to create a model to identify the risk of collision around the crossing point. ATCOs’ response time was used as the performance indicator in the study. It was found that the increase in flight time and the number of aircraft around the crossing point lead to an increased risk of collision. Factors like the number of aircraft in the entire sector and the headings of the aircraft around the crossing point were factors affecting the overall flight time and the number of aircraft around crossing point respectively. Using thresholds on the flight time and the number of aircraft, the model created was able to characterise the crossing points into 3 levels of risk. This helps to distinguish crossing points with higher chances of conflicts being missed out.
author2 Lye Sun Woh
author_facet Lye Sun Woh
Tan, Brenda Teresa Li Min
format Final Year Project
author Tan, Brenda Teresa Li Min
author_sort Tan, Brenda Teresa Li Min
title Time density approach to managing en-route airspace
title_short Time density approach to managing en-route airspace
title_full Time density approach to managing en-route airspace
title_fullStr Time density approach to managing en-route airspace
title_full_unstemmed Time density approach to managing en-route airspace
title_sort time density approach to managing en-route airspace
publisher Nanyang Technological University
publishDate 2020
url https://hdl.handle.net/10356/141169
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